As solar storms go, the Valentine’s Day flare was actually modest. But the burst of activity is only the start of the upcoming solar maximum, due to peak in the next couple of years.

“The sun has an activity cycle, much like hurricane season,” Tom Bogdan, director of the Space Weather Prediction Center in Boulder, Colorado, said earlier this month at a meeting of the American Association for the Advancement of Science in Washington, D.C.

“It’s been hibernating for four or five years, not doing much of anything.” Now the sun is waking up, and even though the upcoming solar maximum may see a record low in the overall amount of activity, the individual events could be very powerful.

In fact, the biggest solar storm on record happened in 1859, during a solar maximum about the same size as the one we’re entering, according to NASA.

That storm has been dubbed the Carrington Event, after British astronomer Richard Carrington, who witnessed the megaflare and was the first to realize the link between activity on the sun and geomagnetic disturbances on Earth.

The flares were so powerful that “people in the northeastern U.S. could read newspaper print just from the light of the aurora,” Daniel Baker, of the University of Colorado’s Laboratory for Atmospheric and Space Physics, said at a geophysics meeting last December.

In addition, the geomagnetic disturbances were strong enough that U.S. telegraph operators reported sparks leaping from their equipment—some bad enough to set fires, said Ed Cliver, a space physicist at the U.S. Air Force Research Laboratory in Bedford, Massachusetts.

In 1859, such reports were mostly curiosities. But if something similar happened today, the world’s high-tech infrastructure could grind to a halt.

To begin with, the University of Colorado’s Baker said, electrical disturbances as strong as those that took down telegraph machines—”the Internet of the era”—would be far more disruptive. (See “The Sun—Living With a Stormy Star” in National Geographic magazine.)

Solar storms aimed at Earth come in three stages, not all of which occur in any given storm.

Finally comes a coronal mass ejection, or CME, a slower moving cloud of charged particles that can take several days to reach Earth’s atmosphere. When a CME hits, the solar particles can interact with Earth’s magnetic field to produce powerful electromagnetic fluctuations. (Related: “Magnetic-Shield Cracks Found; Big Solar Storms Expected.”)

“We live in a cyber cocoon enveloping the Earth,” Baker said. “Imagine what the consequences might be.”

Of particular concern are disruptions to global positioning systems (GPS), which have become ubiquitous in cell phones, airplanes, and automobiles, Baker said. A $13 billion business in 2003, the GPS industry is predicted to grow to nearly $1 trillion by 2017.

In addition, Baker said, satellite communications—also essential to many daily activities—would be at risk from solar storms.

“Every time you purchase a gallon of gas with your credit card, that’s a satellite transaction,” he said.

But the big fear is what might happen to the electrical grid, since power surges caused by solar particles could blow out giant transformers. Such transformers can take a long time to replace, especially if hundreds are destroyed at once, said Baker, who is a co-author of a National Research Council report on solar-storm risks.

The U.S. Air Force Research Laboratory’s Cliver agrees: “They don’t have a lot of these on the shelf,” he said.

The eastern half of the U.S. is particularly vulnerable, because the power infrastructure is highly interconnected, so failures could easily cascade like chains of dominoes.

“Imagine large cities without power for a week, a month, or a year,” Baker said. “The losses could be $1 to $2 trillion, and the effects could be felt for years.”

Even if the latest solar maximum doesn’t bring a Carrington-level event, smaller storms have been known to affect power and communications.

The “Halloween storms” of 2003, for instance, interfered with satellite communications, produced a brief power outage in Sweden, and lighted up the skies with ghostly auroras as far south as Florida and Texas.

One solution is to rebuild the aging power grid to be less vulnerable to solar disruptions.

Another is better forecasting. Scientists using the new Solar Dynamics Observatory spacecraft are hoping to get a better understanding of how the sun behaves as it moves deeper into its next maximum and begins generating bigger storms. (See some of SDO’s first sun pictures.)

These studies may help scientists predict when and where solar flares might appear and whether a given storm is pointed at Earth.

“Improved predictions will provide more accurate forecasts, so [officials] can take mitigating actions,” said Rodney Viereck, a physicist at the Space Weather Prediction Center.

Even now, the center’s Bogdan said, the most damaging emissions from big storms travel slowly enough to be detected by sun-watching satellites well before the particles strike Earth. “That gives us [about] 20 hours to determine what actions we need to take,” Viereck said.

In a pinch, power companies could protect valuable transformers by taking them offline before the storm strikes. That would produce local blackouts, but they wouldn’t last for long.

“The good news is that these storms tend to pass after a couple of hours,” Bogdan added.

Meanwhile, scientists are scrambling to learn everything they can about the sun in an effort to produce even longer-range forecasts.

According to Vierick, space-weather predictions have some catching up to do: “We’re back where weather forecasters were 50 years ago.”